KR101951214B1 - CCTV pole management system utilizing solar light with unexpected situation recording function - Google Patents

Abstract

The present invention relates to a CCTV pole management system using sunlight with an unexpected situation recording function and a method thereof. To this end, the CCTV pole management system using sunlight with the unexpected situation recording function comprises: a pole (100) installed on the ground surface; one or more CCTVs (200) installed on the pole (100) to observe a pre-designated surveillance district; one or more detectors (300) installed on the pole (100) to detect an object which approaches the pole (100); a repeater which receives and transmits the details detected by the detectors (300); and an enclosure (400) installed on the pole (100) to have a door opened towards a front side, to include: a control module which controls the CCTVs (200), and an analysis module which analyzes the details received from the repeater, and to have a sunlight module (500) formed on an external surface to be able to supply electric power. The present invention aims to the CCTV pole management system using sunlight with the unexpected situation recording function and the method thereof, which are able to minimize power consumption required for operating the CCTVs by using solar power and to operate the CCTVs even when electric power is not supplied.

Description

[0001] CCTV pole management system and method using photovoltaic with sudden situation recording [0002] A CCTV pole management system using solar light with unexpected situation recording function [

The present invention is a system in which a system box called CCTV, which controls the power, communication, and amplifier of a CCTV, controls the CCTV pole, and is supplied with power from the sunlight and uses a shock sensor, a pressure sensor, The present invention relates to an apparatus for analyzing a cause of an accident,

CCTV (Closed-circuit Television) monitors the surveillance range installed and set in the designated surveillance range. Conversely, there is an open-circuit television, or open-circuit television, which usually refers to a TV and is meant to be seen by an unspecified number of people. Closed-circuit TV therefore means TV provided to specific people for specific purposes. For this purpose, CCTV is called closed circuit TV because it is not connected to outside by radio.

Generally, the CCTV is installed in the monitoring range and receives the power to monitor the set monitoring range. At this time, when supplying power to the CCTV, a separate enclosure (single box) is provided around the CCTV installed, and the electric power supplied to the enclosure is converted into electric power available for the CCTV to distribute the electric power.

However, it is exposed to the risk of electric power accident because electric power supply to CCTV is cut off due to power shortage such as electric wire shortage, electric supply company's supply insecurity, and power outage in the area, or electric power may be cut off due to deliberate loss.

When the power supplied to the CCTV is cut off, the operation of the CCTV is interrupted. Since the operation of the CCTV is stopped and the crime or accident occurring within the monitoring range can not be monitored during the interrupted time, There is a problem in that it can not perform its function.

Also, as described above, in order to monitor crimes or accidents occurring within the detection range of the CCTV, the CCTV must operate at all times, thereby increasing the power consumption required.

In order to solve the above problems, there have recently been developed technologies that use natural energy to convert electric power and use converted electric power. Among them, photovoltaic power generation that can be used for a long time without the depletion of resources is attracting attention .

Solar power generation is a power generation technology that converts solar light energy to produce electricity. It consists of a solar cell module, a battery, and a power conversion unit. A photovoltaic cell designed to convert solar energy into electrical energy. It uses photovoltaic power generated by photoelectric effect when light is irradiated on the contact surface of metal and semiconductor or the PN junction of semiconductor. Selenium photovoltaic cells and sulfurous copper photovoltaic cells have been used to make contact with metals and semiconductors. Silicon photovoltaic cells, which are used as solar cells, include semiconductor PN junctions. As a power generation principle by PN junction, solar cell is a semiconductor typified by silicon and developed naturally by the development of semiconductor technology and semiconductor characteristics. Solar cells have a structure in which N (negative) type semiconductors having different electrical properties and P (positive) type semiconductors are bonded. The two semiconductor boundary portions are referred to as PN junctions. When light comes in, sunlight is absorbed into the solar cell, and the energy of the absorbed sunlight causes electrons (holes) and electrons (+) Is collected toward the P-type semiconductor, so that the potentials are generated. Therefore, the front and back (front and back) If a load such as a motor or a motor is connected to the electrode attached to the electrode, electric current flows. This is the principle of the solar power generation by the PN junction of the solar cell.

In addition, many CCTV cameras are located in "Poles" throughout the country. In the pole, the image is transmitted from the system box called " enclosure " to the control center using power, communication, and an amplifier. However, there is no system or mechanism to manage the "pole", which is the main axis of such facilities. Such CCTV camera poles can cause wasted budget because it causes frequent accidents caused by impact and it is difficult to analyze the cause immediately.

KR 10-1459104 B1 KR 10-1291728 B1 KR 10-1594800 B1 KR 10-1332683 B1

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to minimize the power consumption required for CCTV operation by using solar power and to operate the CCTV even when power is cut off, The present invention provides a housing and a method for managing a CCTV pole using solar light for instantly transmitting an image of an impacted person by designating a preset at a time of a certain impact using a proximity sensor.

In order to achieve the above object, the present invention provides a CCTV pole management system using solar light having an unexpected event recording function, comprising: a pole 100 installed on the ground; At least one CCTV (200) installed in the pole (100) for monitoring a predetermined monitoring area; At least one detector (300) installed at the pole (100) for sensing an object approaching the pole (100); A relay for receiving and transmitting the details detected by the detector 300; And a door provided in the pole 100 for opening forward and includes a control module for controlling the CCTV 200 and an analysis module for analyzing the details received from the relay device , And a solar cell module (500) is formed on an outer surface of the housing (400) to supply electric power.

The present invention has the effect of minimizing the power required for CCTV operation because the solar power and the commercial power can be used together. In addition, since the power charged by the sunlight can be used even in the event of a power failure such as a breakdown of commercial power, it has the effect of securing electric power for CCTV operation until the supply of commercial power is restored. Or by using a proximity sensor to specify a preset in case of impact over a certain period of time to instantly transmit an image of the impacted spot to prevent accidents that might occur in the future and to manage and protect the CCTV pole, have.

1 is an embodiment of a CCTV pole management system utilizing solar light having an unexpected state recording function according to the present invention.
FIG. 2 is a CCTV pole and its enclosure utilizing solar light having an unexpected situation recording function according to the present invention.
3 is a perspective view of a part of a pressure sensing sensor according to the present invention.
4 shows the configuration of an infrared sensor according to the present invention.
5 is an illustration of a solar module and configuration included in the enclosure according to the present invention.
FIG. 6 is an embodiment of a CCTV polling management method using solar light having an unexpected situation recording function according to the present invention.
7 is a block diagram illustrating an example of using a PTZ camera according to the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings, but the present invention is not limited by the scope of the present invention.

A CCTV pole management system using solar light having an unexpected event recording function according to the present invention includes: a pole 100 installed on the ground; At least one CCTV (200) installed in the pole (100) for monitoring a predetermined monitoring area; At least one detector (300) installed at the pole (100) for sensing an object approaching the pole (100); A relay for receiving and transmitting the details detected by the detector 300; And a door provided in the pole 100 for opening forward and includes a control module for controlling the CCTV 200 and an analysis module for analyzing the details received from the relay device , And a solar cell module (500) is formed on an outer surface of the housing (400) to supply electric power.

1, when the vehicle approaches the pressure sensor unit 310 in the course of colliding with the poles 100 of the CCTV by the approach of the vehicle, the pressure sensor unit 310 detects the pressure sensor unit 310, And transmits the details to the repeater, and the repeater transmits the analyzed information to the analysis module of the housing by the wired or wireless communication method. At this time, the infrared sensor 320 detects the speed and the distance of the approaching vehicle and transmits it to the repeater, and the repeater transmits the signal to the analysis module. Based on the information received from the pressure sensor unit 310 and the infrared sensor unit 320, the analysis module measures the risk of collision with the CCTV pole 100, such as when approaching the vehicle, Take the command to the module and turn the CCTV camera to the appropriate position. The details such as the screen, location, and speed are recorded and sent to the administrator and the central control center.

2, the CCTV 200, the pole 100, and the photovoltaic module 500 are mounted on the outer surface of the CCTV pole and the enclosure using the solar light having the unexpected state recording function according to the present invention. The enclosure 400 can be seen.

3, the pressure sensing unit 310 according to an embodiment of the present invention includes a first cover layer 311, a first electrode 312, an intermediate layer 313, a second electrode 314, 2 < / RTI > cover layer 315. FIG.

The first cover layer 311 and the second cover layer 315 surround and support the first electrode 312, the intermediate layer 313, and the second electrode 314.

The first electrode 312 and the second electrode 314 are each made of a fabric including conductive fibers. The first electrode 312 may include a first conductive region formed in a first direction and the second electrode 314 may include a second conductive region formed in a second direction different from the first direction . The intermediate layer 313 is disposed between the first electrode 312 and the second electrode 314 and is resilient and has a higher resistance than the first electrode 312 and the second electrode 314. At this time, the intermediate layer 313 may also include a fibrous substrate.

When the first electrode 312 and the second electrode 314 are fabric and the intermediate layer 313 includes a fibrous base material, the pressure sensing sensor portion 310 is flexible, so that the risk of breakage is small, There is no restriction on the radius, and a double surface can be realized.

Further, when the first electrode 320 and the second electrode 340 include a conductive region formed in different directions, it is possible to recognize a coordinate according to the overlapping point between the first conductive region and the second conductive region, Can be accurately detected. Accordingly, a plurality of sensor nodes can be included in one pressure sensing sensor unit 310, and large area scanning is possible.

In addition, when the intermediate layer 313 is elastic, the thickness D 'of the intermediate layer 313 is reduced at the pressing point as shown in FIG. When the resistance of the intermediate layer 313 is greater than the resistance of the first electrode 312 and the second electrode 314, for example, the resistance of the intermediate layer 313 is higher than that of the first electrode 312 and the second electrode 314. [ When the resistance is 10 times or more, preferably 100 times or more, and more preferably 1000 times or more of the resistance, the intermediate layer 313 has an insulating function in a steady state. However, when a pressure is applied on the pressure sensing part 310, the thickness D 'of the intermediate layer 313 is reduced, and the resistance or permittivity is changed. Accordingly, the piezoresistance or capacitance can be easily and reliably Can be detected.

4 shows a configuration of an infrared sensor unit 320 according to the present invention.

The infrared sensor 320 includes a body 323 for receiving the light emitting element 324 and the light receiving element 325 and a lens 322 formed on the light emitting element 324 and the light receiving element 325. [ And a lens unit 321 coupled with the lens unit 323.

At this time, the infrared sensor unit 320 may include one light emitting device 324 and one light receiving device 325. Accordingly, the CCTV pole management system using the solar light having the unexpected state recording function according to the present invention can be configured to detect the speed and direction of the approaching object.

At this time, the solar module 500 is formed on the outer surface of the housing 400 as described above.

Here, the solar module 500 is installed on at least one of the upper surface, the lower surface, the left surface, and the right surface of the housing 400. In addition, the solar module 500 can be formed on the enclosure 400 to have a predetermined inclination, thereby enlarging an area where the sunlight is collected, thereby allowing the sunlight to be efficiently incident on the enclosure 400. Also, it goes without saying that a black box device for storing information from the sensor units 310 and 320 together with the CCTV may be connected to the enclosure 400 according to other conditions. This is a configuration for achieving the purpose of uninterruption and surveillance according to the present invention. Such a black box device is generally known and common technology, and a detailed description thereof will be omitted.

The photovoltaic module 500 uses a conventional photovoltaic module in which the photovoltaic cells are gathered to receive sunlight (light) and convert it into electric power. The photovoltaic module 500 may be fabricated as a dual-panel structure or a single-layer panel structure in which the photovoltaic module 500 is stacked. This is because it is sufficient to achieve only the purpose of converting power into sunlight (light) to supply electric power to the device, and the present invention can utilize the power converted into sunlight (light) regardless of the type of the solar module That's enough.

5 schematically shows a solar module 500 included in the enclosure 400 according to the present invention and its configuration. The embodiment of the present invention according to the present invention may include a first battery 501, a second battery 502, an auxiliary storage unit 503, a power shutdown unit, an accident detection unit, a power control unit 505 And a direction control unit 160 are included. The first storage battery 501 is charged with electric power by the solar module and is used as emergency power in the event of a power failure such as a power failure under the control of the enclosure 400. [ The second storage battery 502 is charged by the solar module and is used before the commercial power 504 under the control of the enclosure 400. [ However, in order for the second battery 502 to be used before the commercial power 504, the amount of power charged in the second battery must be charged to a predetermined amount. In other words, according to the present invention, when the amount of charge of the second storage battery 502 is equal to or greater than a predetermined amount, the commercial power can be shut off and the power of the second storage battery 502 can be used under the control of the enclosure 400. When the amount of charge of the second storage battery 502 is less than a certain amount, the supply of the commercial power is resumed. To this end, the enclosure 400 includes a power cutoff unit and an accident detection unit. The power cut-off unit cuts off the supply of the commercial power in order to use the electric power charged in the second accumulator battery before the commercial power. As described above, the commercial power is cut off by the power cut-off unit and the electric power charged in the second storage battery 502 is supplied to the CCTV. The accident detection unit detects whether the commercial power is smoothly supplied to the enclosure 400, and when the commercial power supply is not smooth, it senses and judges by a power accident and supplies emergency power. Accordingly, when the accident detection unit senses a power accident, the electric power charged in the first storage battery 501 is used. In this case, when the first storage battery 501 is used, a case where a power failure such as a short circuit accident is detected in the enclosure 400, can be notified to the control room when a power failure is detected. Therefore, in the event of a power accident, it is possible to notify the relevant government office (for example, KEPCO) promptly. In addition, as described above, the enclosure 400 can discriminate whether the power supplied to the CCTV through the power interruption unit or the accident detection unit is disconnected due to a power accident or blocked by the system. The power control unit 505 controls the use of electric power to supply electric power charged in the first accumulator battery 501 or the second accumulator battery 502 to the apparatus. Therefore, the power control unit 505 can intermittently supply or supply the power of the first accumulator battery 501 or intermittently supply or supply the power of the second accumulator battery 502, as described above. In other words, the second battery 502 is preferentially charged with respect to the first battery 501. This means that when both of the first battery 501 and the second battery 502 are not fully charged, When the first battery 501 is charged while the first battery 501 is charged with power while the commercial power or the power of the second battery 502 is used, the second battery 502 is charged. As a result, emergency power can be secured at all times. However, in the event of a power failure such as a breakdown of commercial power, it may be difficult to maintain power until the commercial power supply is resumed with only the first battery and the second battery. Therefore, it is possible to further include an auxiliary storage unit other than the first storage battery 501 and the second storage battery 502. The auxiliary storage unit 503 charges electric power by the solar module 500 and supplies power to the first storage battery 501 and the second storage battery 502 under the control of the enclosure 100. [ The auxiliary storage unit 503 includes a charged amount detection module, and the charged amount detection module detects the amount of power charged in the first storage battery 501 and the second storage battery 502. [ Accordingly, power can be supplied according to the amount of electric power charged in the first storage battery 501 and the second storage battery 502. For example, the commercial power is cut off by the power cut-off unit, and the electric power charged in the second accumulator 502 is supplied. In the case where the second accumulator 502 is in the predetermined setting (when the charge amount of the second accumulator is 40% The power of the auxiliary storage unit 503 is supplied in accordance with the charged amount detected by the charged amount detecting module.

In other words, the storage capacity of the second storage battery 502 is detected through the storage capacity detection module of the auxiliary storage unit 503. In this case, when the storage capacity of the second storage battery 502 is detected as a pre- And supplies power to the two-battery 502. For example, in the case where the power of the second storage battery 502 is set to be interrupted when the storage amount of the second storage battery 502 is set to 40%, the power of the second storage battery 502 is detected to be 45% The power is supplied from the auxiliary storage unit 503.

The predetermined numerical values (40% and 45%) described above are described in order to facilitate understanding of the present invention, and this may vary depending on the setting of the operator, and the numerical values described above are not limited to the present invention It is natural.

The power supply of the above-described auxiliary storage unit 503 can also be applied to the case of the first storage battery 501. [

That is, the first battery 501 is a battery that charges electric power used in an emergency, and can receive the electric power charged in the auxiliary storage unit 503 by detecting the charged amount as described above.

In addition, the control of the interruption and supply of power as described above can be performed by the power control unit 505, but may also be performed in the control room.

The adjustment and control of the angle of the solar module 500 formed on the housing 400 may be performed not only by manual operation of the operator but also by setting the scheduling as described above. The scheduling to be set at this time may be set differently according to a preset period such as a quarter, a half, a season, and a month, because the height and the copper line of the sun are changed according to the period. Depending on other conditions, the scheduling may be set differently based on the amount of sunlight (light) incident on the sunshine region or the latitude / longitude region.

As described above, the present invention includes a first battery 501, a second battery 502, and an auxiliary storage unit 503. In this case, the first storage battery 501 and the second storage battery 503 are charged by the sunlight (light) 501, the second storage battery 502, and the auxiliary storage unit 503 in this order. Therefore, it is possible to increase the amount of electric power that can be used in case of an emergency, so that emergency power can be used more effectively in the event of a power failure such as a short circuit due to intentional loss or a power failure, .

Next, FIG. 6 is an embodiment of a method for managing a CCTV pole using solar light having an unexpected state recording function according to the present invention. Sensing by the sensor 300, transmitting the details detected by the sensor 300 to the control module through the repeater, checking the number of the pressure sensing unit 310, analyzing the position of the sensed object, And the risk is measured through information such as location and speed in the analysis module. Correcting the error of the detected details, turning the CCTV screen according to the analyzed PTZ value, and storing the detected details and images on a storage medium such as a black box And then transmitting the history and the image to the administrator and the central control center.

In order to facilitate understanding of the present invention, an embodiment of a method of managing a CCTV pole using sunlight having an unexpected event recording function according to the present invention described above is described. The pressure detection sensor unit 310 includes a pressure sensor unit (320) or can be used together. The range of the present invention is not limited to the pressure sensor unit 310 and the infrared sensor unit 320 as the types of the detectors 300.

As a method of measuring the risk proposed in the present invention, a braking distance of a vehicle corresponding to the speed is calculated by receiving the speed and direction of an approaching object detected through the sensor units 310 and 320, The time is over. When the risk at the standard speed is 100, when the speed of 80% is detected, rotate the CCTV screen and shoot.

The predetermined numerical values (100 and 80%) described above are described in order to facilitate understanding of the present invention, and this may vary depending on the setting of the operator, and the above-described numerical values are not limited to the present invention Of course.

7 is a block diagram schematically showing a mode control module included in the PTZ camera image control system according to the embodiment of the present invention. The mode control module according to the present embodiment includes a signal acquisition unit, a mode control unit, a preset setting unit, and an image output unit. The signal acquisition unit performs an operation of acquiring various signals in cooperation with the controller device. The signal obtaining unit receives an operation signal for controlling the mode of the image photographing apparatus from the controller apparatus according to the operation or input of the user. Here, the operation signal may be a PTZ operation signal, an OSD operation signal, an OSD maintenance signal, or the like. For example, the PTZ operation signal is a signal for controlling (changing) the shooting area of the PTZ camera, and the OSD operation signal is a signal for outputting and controlling the OSD menu for image setting of the shot image. Means a signal for changing the shooting area of the PTZ camera while maintaining the OSD menu. Such an operation signal may be an independent signal, but is not limited thereto, and may be an operation signal in which one or more signals are combined. The mode control unit determines an operation mode based on the operation signal acquired by the signal acquisition unit, and performs control corresponding to the determined mode. The mode control unit determines whether one of the PTZ mode, the OSD setting mode, the OSD holding mode, and the like is entered based on the operation signal. For example, the mode control unit determines the entry of the PTZ mode when the PTZ operation signal is received, and determines the entry of the OSD setup mode when the OSD operation signal is received. Also, the mode control unit determines the entry of the OSD holding mode when the OSD holding signal is received. Here, the OSD holding signal may be received in a form included in the PTZ operation signal. The mode control unit controls the photographing area of the PTZ camera based on the PTZ operation signal when entering the PTZ mode. In other words, in the PTZ mode, the mode control unit can change the shooting area by controlling functions of the PTZ camera such as Pan, Tilt, and Zoom according to the PTZ operation signal. For example, when the mode control unit first enters the PTZ mode, the PTZ camera captures the photographed image of the first region in the range of 0 to 120 degrees, and based on the PTZ operation signal input after the photographing of the first region, The control unit may control the control unit so that the photographed image of the second area in the range of 240 to 360 may be photographed based on the input PTZ operation signal after the photographing of the second area, . The mode control unit controls the OSD menu based on the OSD operation signal when the OSD setting mode is entered. The mode control unit overlays the captured image in the presence of the previously captured image so that the OSD menu is output, and performs setting of the OSD menu based on the OSD operation signal. For example, upon entering the OSD setting mode, the mode control unit outputs the main menu, and can enter the first submenu, the second submenu, or the like based on the OSD operation signal. The preset setting unit performs an operation of storing and managing settings for each photographed image photographed in a plurality of areas. The preset setting unit stores the respective OSD setting information when the OSD setting for each shot image for the plurality of areas is completed by the mode control unit. The stored OSD setting information may be provided when the PTZ camera performs a shooting or monitoring operation on the area. The image output unit transmits the photographed image photographed by the PTZ camera to the video output device and outputs the OSD menu when the output of the OSD menu is required based on the mode determined by the mode control unit.

The embodiment of the mode control module included in the above-described PTZ camera image control system according to the present invention is an example of using a PTZ camera as a kind of camera used in CCTV to help understand the present invention. Therefore, a fixed camera or a front-facing camera, including a PTZ camera, may be applied.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

100: Poles
200: CCTV
300: Detector
400: enclosure
500: Solar module

Claims (6)

A pole 100 installed on the ground;
At least one CCTV (200) installed in the pole (100) for monitoring a predetermined monitoring area;
At least one detector (300) installed at the pole (100) for sensing an object approaching the pole (100);
A repeater for receiving the details detected by the detector 300,
A control module for controlling the CCTV 200 and an analyzing module for analyzing the details received from the repeater are provided inside the pole 100 and a door opening forward, And a solar cell module (500) formed on the outer surface of the housing (400)
The detector (300)
At least one pressure sensing sensor unit (310) for sensing pressure and position information according to an applied weight;
The sensor 400 senses the approaching object to the pole 100 by receiving the pressure and the positional information from the pressure sensing sensor 310 and transmits the position and velocity information to the analysis module of the housing 400 A detection signal processing unit 316;
An infrared sensor unit 320 which periodically emits infrared rays for a predetermined period of time and detects the reflected infrared rays emitted from the emitted luminescent infrared ray reflected by an external object; And
The infrared sensor 320 receives the result of sensing the reflected infrared rays and senses the approaching object to the pole 100 to transmit the position and velocity information to the control module of the enclosure 400. [ And a signal processing unit 326,
The pressure-sensing sensor unit 310 includes a pressure-
A first electrode layer 312, an intermediate layer 313, a second electrode 314 and a second cover layer 315,
The first cover layer 311 and the second cover layer 315 surround and support the first electrode 312, the intermediate layer 313, and the second electrode 314,
The first electrode 312 and the second electrode 314 are each made of a fabric including conductive fibers,
The intermediate layer 313 is disposed between the first electrode 312 and the second electrode 314 and is resilient and has a higher resistance than the first electrode 312 and the second electrode 314,
The solar module (500)
And is formed on at least one of an upper surface, a lower surface, a left surface, and a right surface of the housing 400,
The housing (400)
A first storage battery 501 that is charged by the solar module 500 and used in an emergency;
A second storage battery 502 charged by the solar module 500 and used prior to the commercial power 504; And
And an auxiliary storage unit (503) for storing electric power by the solar module (500)
The auxiliary storage unit 503,
Supplies power to the first battery (501) or the second battery (502) under the control of the enclosure (400);
Wherein the control unit detects an amount of charge of the first storage battery (501) or the second storage battery (502), and supplies power to the storage battery when the detected amount of charge is less than an amount required for driving CCTV pole management system using solar light.
The apparatus of claim 1, wherein the detector (300)
At least one pressure sensing sensor unit (310) for sensing pressure and position information according to an applied weight; And
The sensor 400 senses the approaching object to the pole 100 by receiving the pressure and the positional information from the pressure sensing sensor 310 and transmits the position and velocity information to the analysis module of the housing 400 And a detection signal processing unit (316). The CCTV pole management system utilizes solar light having an unexpected state recording function.
The apparatus of claim 1, wherein the detector (300)
An infrared sensor unit 320 which periodically emits infrared rays for a predetermined period of time and detects the reflected infrared rays emitted from the emitted luminescent infrared ray reflected by an external object; And
The infrared sensor 320 receives the result of sensing the reflected infrared rays and senses the approaching object to the pole 100 to transmit the position and velocity information to the control module of the enclosure 400. [ And a signal processing unit (326). The CCTV pole management system utilizes solar light having an unexpected state recording function.
The solar module according to claim 1, wherein the solar module (500)
Wherein the at least one surface of the enclosure (400) is formed on at least one of a top surface, a bottom surface, a left surface, and a right surface of the enclosure (400).
[2] The hood according to claim 1,
A first storage battery 501 that is charged by the solar module 500 and used in an emergency;
A second storage battery 502 charged by the solar module 500 and used prior to the commercial power 504; And
And an auxiliary storage unit (503) for storing electric power by the solar module (500)
The auxiliary storage unit 503,
Supplies power to the first battery (501) or the second battery (502) under the control of the enclosure (400);
And an electric power is supplied to the battery when the amount of charge of the first battery (501) or the second battery (502) is detected and the amount of charge detected is less than an amount required for driving the battery CCTV pole management system using solar light with recording function.
Sensing an object approaching the pole (100) at the sensor (300);
Receiving the details detected by the detector (300), and transmitting the received details to an analysis module in a repeater;
Analyzing a position sensed by the analysis module;
Measuring a risk level in the analysis module;
Correcting an error of the detected details in the analysis module;
If the risk is high, turning the screen of the CCTV to the analyzed position in the step of analyzing the position;
Storing the detected history and image in a predetermined storage medium until the risk level falls to a predetermined value;
And transmitting the history and the image stored in the storage medium to a manager's mobile phone and a central control center.

Images